Showing all 4 results

  • Kingwin Optics CaF2 Plano-concave LensesKingwin Optics CaF2 Plano-concave Lenses

    CaF2 Plano-concave Lenses

    Wide Spectral Transmission Range: CaF2 lenses offer a very wide transmission range, typically from the ultraviolet (UV) region at around 150 nm to the infrared (IR) region at up to 8 µm. This wide transmission range makes them suitable for applications requiring light manipulation across multiple spectral bands.

    Excellent UV Transmittance: CaF2 exhibits excellent ultraviolet transmittance, making it an ideal material for UV optics. This property is particularly useful in applications such as UV spectroscopy, UV imaging, and UV laser systems.

    High Laser Durability: CaF2 has a high laser-induced damage threshold (LIDT), which means it can withstand high laser power without significant degradation. This high laser durability makes CaF2 plano-concave lenses suitable for use in high-power laser systems and applications.

    Low Fluorescence: Compared to some other optical materials, CaF2 has minimal fluorescence, which helps reduce background noise in imaging and spectroscopic applications.

    Customizable Designs: Many manufacturers offer CaF2 plano-concave lenses with customizable dimensions, focal lengths, and coatings to meet specific application requirements. This flexibility allows users to tailor the lenses to their exact needs.

    Precision Optics: CaF2 plano-concave lenses are often manufactured to precise specifications, ensuring high optical quality and performance. This precision is crucial for applications requiring accurate light manipulation and focusing.

    Versatility: Due to their wide transmission range and excellent optical properties, CaF2 plano-concave lenses find applications in various fields, including scientific research, medical and biotech, environmental monitoring, aerospace and defense, and industrial applications.

    Compatibility with Advanced Coatings: CaF2 lenses can be coated with various anti-reflection (AR) coatings to further enhance their optical performance. These coatings can be tailored to specific wavelengths and applications, providing optimal transmission and reflection properties.

    Applications: Ultraviolet (UV) and Infrared (IR) Optics, Beam Expansion and Collimation, Imaging Systems, Laser Optics, Optical Communications, Scientific Research and Instrumentation, etc.

  • Kingwin Optics λ10 UV Fused Silica Plano-concave LensesKingwin Optics λ10 UV Fused Silica Plano-concave Lenses

    λ10 UV Fused Silica Plano-concave Lenses

    Excellent UV Transmission:

    UV fused silica, also known as UV-grade fused silica, is known for its high transmission in the UV range, typically from 190 nm to 2600 nm, depending on the coating. This makes it an ideal material for plano-concave lenses designed to work in the UV spectrum.

    Low Fluorescence and Laser-Induced Damage Threshold:

    UV fused silica exhibits virtually no laser-induced fluorescence, ensuring that the material does not emit light when excited by UV radiation. This is crucial for applications where fluorescence could interfere with measurements or imaging.

    It also has a high laser-induced damage threshold, allowing it to withstand high-intensity laser beams without degrading.

    Surface Quality and Accuracy:

    The λ/10 surface irregularity specification indicates that the surface deviations from a perfect shape are kept to within one-tenth of the wavelength of light used, typically at 633 nm. This level of precision ensures minimal wavefront distortions and optical aberrations.

    • The lenses may also have other surface quality specifications, such as a 40-20 scratch-dig rating, which guarantees a smooth surface with minimal defects.

    Material Homogeneity and Stability:

    UV fused silica has better homogeneity and a lower coefficient of thermal expansion than some other optical materials, such as N-BK7. This results in less variation in optical properties across the lens and improved stability under changing temperature conditions.

    Diverging Ability:

    As plano-concave lenses, they have a negative focal length, enabling them to diverge collimated beams. This property is useful in applications where beam expansion or projection is required.

    Customizable Coatings:

    UV fused silica plano-concave lenses can be coated with various antireflection (AR) coatings optimized for specific wavelength ranges, including those in the UV spectrum. This minimizes reflections and maximizes transmission over the desired wavelengths.

    Wide Range of Sizes and Focal Lengths:

    These lenses are available in various diameters and focal lengths, allowing for flexibility in system design. This ensures that there is a suitable lens for a wide range of applications.

    Compatibility and Mounting Options:

    UV fused silica plano-concave lenses are often compatible with standard optical mounts and components, facilitating integration into existing optical systems.

    Applications: Laser scanners, remote sensing, imaging instruments, fiber lasers, interferometers, and other optical systems, etc.

  • Kingwin Optics λ4-λ N-BK7 Plano-concave LensesKingwin Optics λ4-λ N-BK7 Plano-concave Lenses

    λ4-λ N-BK7 Plano-concave Lenses

    High Optical Quality:

    The λ4 surface accuracy ensures precision optical performance, minimizing wavefront distortions and optical aberrations.

    The 40-20 scratch-dig surface quality guarantees excellent surface smoothness, reducing scattering and unwanted diffraction effects.

    Broad Wavelength Range:

    These lenses are typically designed for operation across a wide wavelength range, although the exact range may vary depending on the coating and intended application. N-BK7 glass itself has a transmission range from 350 nm to 2.0 μm (uncoated), making it suitable for both visible and near-infrared applications.

    Material Properties:

    N-BK7 is a high-quality borosilicate crown glass known for its excellent homogeneity, low bubble and inclusion content, and ease of manufacturing.

    It offers a good balance of transmission, durability, and cost-effectiveness, making it a popular choice for many optical components.

    Focal Length and Diverging Ability:

    Plano-concave lenses have a negative focal length, enabling them to diverge collimated beams. This property makes them useful in applications where beam expansion or divergence is required.

    Versatility:

    Available in various diameters, including 6 mm, 9 mm, 1/2″, 25 mm, 1″, and 2″, allowing for flexibility in system design.

    Focal lengths can also vary widely, offering a range of options to suit different applications.

    Antireflection Coatings:

    While the exact coating specifications may not be directly stated as “λ4-λ” in the context of this question, N-BK7 plano-concave lenses can be coated with various antireflection (AR) coatings to minimize reflections and maximize transmission over specific wavelength ranges. This can improve overall optical efficiency.

    Applications: Laser Scanners, Remote Sensing Instruments, Imaging Instruments, Fiber Lasers, Interferometers, etc.

  • Kingwin Optics λ4-λ UV Fused Silica Plano-concave LensesKingwin Optics λ4-λ UV Fused Silica Plano-concave Lenses

    λ4-λ UV Fused Silica Plano-concave Lenses

    Negative Focal Length and Spherical Aberration: Ideal for diverging collimated light beams and improving image qualities.

    Wide Range of Applications: Suitable for laser scanners, remote sensing, imaging instruments, fiber lasers, interferometers, and more.

    High-Quality Material: Made from UV Fused Silica or Corning High Purity UV Fused Silica Glass, ensuring superior transmission in the UV region and high chemical inertness.

    Customizable Focal Lengths and Diameters: Focal lengths range from -10mm to -150mm, with diameters ranging from 6.0mm to 50.8mm. Other focal lengths can be customized.

    Strict Quality Control: Each lens undergoes strict inspection in Kingwin Optics’ in-house labs to ensure tight tolerance.

    Applications: Laser Scanners, Remote Sensing, Imaging Instruments, Fiber Lasers, Interferometers, etc.